/* IBM_PROLOG_BEGIN_TAG */ /* This is an automatically generated prolog. */ /* */ /* $Source: src/usr/targeting/targetservicestart.C $ */ /* */ /* OpenPOWER HostBoot Project */ /* */ /* Contributors Listed Below - COPYRIGHT 2012,2017 */ /* [+] Google Inc. */ /* [+] International Business Machines Corp. */ /* */ /* */ /* Licensed under the Apache License, Version 2.0 (the "License"); */ /* you may not use this file except in compliance with the License. */ /* You may obtain a copy of the License at */ /* */ /* http://www.apache.org/licenses/LICENSE-2.0 */ /* */ /* Unless required by applicable law or agreed to in writing, software */ /* distributed under the License is distributed on an "AS IS" BASIS, */ /* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or */ /* implied. See the License for the specific language governing */ /* permissions and limitations under the License. */ /* */ /* IBM_PROLOG_END_TAG */ /** * @file targeting/targetservicestart.C * * @brief Hostboot entry point for target service */ //****************************************************************************** // Includes //****************************************************************************** // STD #include #include // Other components #include #include #include #include #include #include #include // This component #include #include // Others #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef CONFIG_DRTM #include #endif using namespace INITSERVICE::SPLESS; //****************************************************************************** // targetService //****************************************************************************** namespace TARGETING { #define TARG_NAMESPACE "TARGETING::" #define TARG_LOC TARG_NAMESPACE TARG_CLASS TARG_FN ": " //****************************************************************************** // _start //****************************************************************************** #define TARG_CLASS "" /* * @brief Initialize any attributes that need to be set early on */ static void initializeAttributes(TargetService& i_targetService, bool i_isMpipl, bool i_istepMode, ATTR_MASTER_MBOX_SCRATCH_type& i_masterScratch); /** * @brief Check that at least one processor of our cpu type is being targeted */ static void checkProcessorTargeting(TargetService& i_targetService); /** * @brief Compute any values that might change based on a remap of memory * @param[in] Pointer to targeting service */ static void adjustMemoryMap(TargetService& i_targetService); /** * @brief Entry point for initialization service to initialize the targeting * code * * @param[in] io_pError * Error log handle; returns NULL on success, !NULL otherwise * * @note: Link register is configured to automatically invoke task_end() when * this routine returns */ static void initTargeting(errlHndl_t& io_pError) { #define TARG_FN "initTargeting(errlHndl_t& io_pError)" TARG_ENTER(); //Need to stash away the master mbox regs as they will //be overwritten bool l_isMpipl = false; bool l_isIstepMode = false; ATTR_MASTER_MBOX_SCRATCH_type l_scratch = {0,0,0,0,0,0,0,0}; for(size_t i=0; i< sizeof(l_scratch)/sizeof(l_scratch[0]); i++) { l_scratch[i] = Util::readScratchReg(MBOX_SCRATCH_REG1+i); } // Check mbox scratch reg 3 for IPL boot options // Specifically istep mode (bit 0) and MPIPL (bit 2) INITSERVICE::SPLESS::MboxScratch3_t l_scratch3; l_scratch3.data32 = l_scratch[SCRATCH_3]; if(l_scratch3.isMpipl) { TARG_INF("We are running MPIPL mode"); l_isMpipl = true; } if(l_scratch3.istepMode) { l_isIstepMode = true; } if(l_scratch3.overrideSecurity) { TARG_INF("WARNING: External tool asked master proc to disable " "security."); } if(l_scratch3.allowAttrOverrides) { TARG_INF("WARNING: External tool asked master proc to allow " "attribute overrides even in secure mode."); } AttrRP::init(io_pError, l_isMpipl); if (io_pError == NULL) { TargetService& l_targetService = targetService(); (void)l_targetService.init(); initializeAttributes(l_targetService, l_isMpipl, l_isIstepMode, l_scratch); checkProcessorTargeting(l_targetService); // Print out top-level model value from loaded targeting values. // @TODO RTC:88056 Make the model printed more meaniful Target* l_pTopLevel = NULL; l_targetService.getTopLevelTarget(l_pTopLevel); ATTR_MODEL_type l_model = MODEL_NA; if (l_pTopLevel->tryGetAttr(l_model)) { TARG_INF("Initialized targeting for model: %s", l_pTopLevel->getAttrAsString()); } #ifdef CONFIG_DRTM const INITSERVICE::SPLESS::MboxScratch7_t scratch7 = {.data32 = l_scratch[SCRATCH_7] }; const INITSERVICE::SPLESS::MboxScratch8_t scratch8 = {.data32 = l_scratch[SCRATCH_8] }; errlHndl_t pError = SECUREBOOT::DRTM::discoverDrtmState( scratch7,scratch8); if(pError) { auto plid = pError->plid(); errlCommit(pError,SECURE_COMP_ID); // TODO: RTC 167205: Better GA error handling INITSERVICE::doShutdown(plid, true); } #endif // Handle possibility of Attribute Overrides allowed in secure mode bool l_allow_attr_overrides = g_BlToHbDataManager.getAllowAttrOverrides(); if (l_allow_attr_overrides) { TARG_INF("Allow Attribute Overrides In Secure Mode: %d", l_allow_attr_overrides); l_pTopLevel->setAttr< TARGETING::ATTR_ALLOW_ATTR_OVERRIDES_IN_SECURE_MODE>( l_allow_attr_overrides); } else { // Hardcode to zero to be safe l_pTopLevel->setAttr< TARGETING::ATTR_ALLOW_ATTR_OVERRIDES_IN_SECURE_MODE>(0x0); } // No error module loaded in VPO to save load time #ifndef CONFIG_VPO_COMPILE // call ErrlManager function - tell him that TARG is ready! ERRORLOG::ErrlManager::errlResourceReady(ERRORLOG::TARG); #endif // set global that TARG is ready Util::setIsTargetingLoaded(); } TARG_EXIT(); #undef TARG_FN } /** * @brief Create _start entry point using task entry macro and vector to * initTargeting function */ TASK_ENTRY_MACRO(initTargeting); /** * @brief Check that at least one processor of our cpu type is being targeted */ static void checkProcessorTargeting(TargetService& i_targetService) { #define TARG_FN "checkProcessorTargeting()" TARG_ENTER(); PredicateCTM l_procChip(CLASS_CHIP,TYPE_PROC); ProcessorCoreType l_coreType = cpu_core_type(); bool l_haveOneCorrectProcessor = false; TargetRangeFilter l_filter( i_targetService.begin(), i_targetService.end(), &l_procChip); for(;l_filter && (l_haveOneCorrectProcessor != true);++l_filter) { switch(l_filter->getAttr()) { case MODEL_VENICE: if(l_coreType == CORE_POWER8_VENICE) { l_haveOneCorrectProcessor = true; } break; case MODEL_MURANO: if(l_coreType == CORE_POWER8_MURANO) { l_haveOneCorrectProcessor = true; } break; case MODEL_NAPLES: if(l_coreType == CORE_POWER8_NAPLES) { l_haveOneCorrectProcessor = true; } break; case MODEL_NIMBUS: if(l_coreType == CORE_POWER9_NIMBUS) { l_haveOneCorrectProcessor = true; } break; case MODEL_CUMULUS: if(l_coreType == CORE_POWER9_CUMULUS) { l_haveOneCorrectProcessor = true; } break; default: break; }; } TARG_ASSERT((l_haveOneCorrectProcessor == true), TARG_ERR_LOC "FATAL: No " "targeted processors are of the correct type"); TARG_EXIT(); #undef TARG_FN } /* * @brief Initialize any attributes that need to be set early on */ static void initializeAttributes(TargetService& i_targetService, bool i_isMpipl, bool i_istepMode, ATTR_MASTER_MBOX_SCRATCH_type& i_masterScratch) { #define TARG_FN "initializeAttributes()...)" TARG_ENTER(); Target* l_pTopLevel = NULL; TargetHandleList l_chips; i_targetService.getTopLevelTarget(l_pTopLevel); if(l_pTopLevel) { Target* l_pMasterProcChip = NULL; i_targetService.masterProcChipTargetHandle(l_pMasterProcChip); if(l_pMasterProcChip) { // Master uses xscom by default, needs to be set before // doing any other scom accesses ScomSwitches l_switches = l_pMasterProcChip->getAttr(); l_switches.useXscom = 1; l_switches.useFsiScom = 0; l_switches.useSbeScom = 0; l_pMasterProcChip->setAttr(l_switches); // Master can only use Host I2C so needs to be set before // doing any I2C accesses I2cSwitches l_i2c_switches = l_pMasterProcChip->getAttr(); l_i2c_switches.useHostI2C = 1; l_i2c_switches.useFsiI2C = 0; l_pMasterProcChip->setAttr(l_i2c_switches); l_pMasterProcChip->setAttr(1); // Master has SBE started l_pMasterProcChip->setAttr(1); l_pTopLevel->setAttr(i_masterScratch); // Targeting data defaults to non istep, only turn "on" if bit // is set so we don't tromp default setting if (i_istepMode) { l_pTopLevel->setAttr(1); } else { l_pTopLevel->setAttr(0); } //Set the RISK_LEVEL ATTR based off of master Scratch regs INITSERVICE::SPLESS::MboxScratch5_t l_scratch5; l_scratch5.data32 = i_masterScratch[INITSERVICE::SPLESS::SCRATCH_5]; if(l_scratch5.riskLevel) { l_pTopLevel->setAttr(1); } } if(i_isMpipl) { l_pTopLevel->setAttr(1); //Clear out some attributes that could have stale data l_pTopLevel->setAttr(0); l_pTopLevel->setAttr(1); //It is possible that the hypervisor moved the HRMOR //The SBE should have read the HRMOR value from the master //core prior to stopping its clocks and passed that //value to the bootloader. The bootloader passes this to //HB via the BlToHbDataManager // Setup physical TOC address uint64_t l_hyp_hrmor = 0; Bootloader::keyAddrPair_t l_keyAddrPairs = g_BlToHbDataManager.getKeyAddrPairs(); for (uint8_t keyIndex = 0; keyIndex < MAX_ROW_COUNT; keyIndex++) { if(l_keyAddrPairs.key[keyIndex] == SBEIO::HYPERVISOR_HRMOR) { l_hyp_hrmor = l_keyAddrPairs.addr[keyIndex]; } } if(l_hyp_hrmor) { l_pTopLevel->setAttr(l_hyp_hrmor); } TARGETING::PredicateCTM l_chipFilter(CLASS_CHIP, TYPE_PROC); TARGETING::PredicateIsFunctional l_functional; TARGETING::PredicatePostfixExpr l_functionalChips; l_functionalChips.push(&l_chipFilter).push(&l_functional).And(); i_targetService.getAssociated( l_chips, l_pTopLevel, TargetService::CHILD_BY_AFFINITY, TARGETING::TargetService::ALL, &l_functionalChips); for (auto & l_chip : l_chips) { l_chip->setAttr(0); l_chip->setAttr(0); //TODO RTC:172534 Need to clear volatile attributes during MPIPL for cumulus } TargetHandleList tpms; TARGETING::PredicateCTM tpmFilter(CLASS_CHIP, TYPE_TPM); i_targetService.getAssociated( tpms, l_pTopLevel, TargetService::CHILD, TARGETING::TargetService::ALL, &tpmFilter); for (auto & tpm : tpms) { tpm->setAttr(0); tpm->setAttr(0); auto tpmMutex=tpm->getHbMutexAttr(); mutex_init(tpmMutex); } } else { l_pTopLevel->setAttr(0); // Compute any values that might change based on a remap of memory adjustMemoryMap(i_targetService); } } else // top level is NULL - never expected { TARG_INF("Top level target is NULL"); } TARG_EXIT(); #undef TARG_FN } /** * @brief Utility macro to swap attributes * @param[in] _attr Attribute ID * @param[in] _master Master proc target * @param[in] _victim Victim proc target * @param[in] _cache Cache of victime attributes */ #define SWAP_ATTRIBUTE( _attr, _master, _victim, _cache ) \ { \ _attr##_type l_masterVal = _master->getAttr<_attr>(); \ _victim->setAttr<_attr>(l_masterVal); \ TARG_INF( "%.8X>" #_attr "=%.16llX", get_huid(_victim), l_masterVal ); \ _master->setAttr<_attr>(_cache[_attr]); \ TARG_INF( "%.8X>" #_attr "=%.16llX", get_huid(_master), _cache[_attr] ); \ } // Compute any values that might change based on a remap of memory static void adjustMemoryMap( TargetService& i_targetService ) { // Grab the value of the BARs that SBE booted with uint64_t l_curXscomBAR = g_BlToHbDataManager.getXscomBAR(); uint64_t l_curLpcBAR = g_BlToHbDataManager.getLpcBAR(); TARG_INF( "adjustMemoryMap> xscom=%llX, lpc=%llX", l_curXscomBAR, l_curLpcBAR ); // Get the master proc Target* l_pMasterProcChip = nullptr; i_targetService.masterProcChipTargetHandle(l_pMasterProcChip); assert(l_pMasterProcChip,"No Master Proc"); // Save off the base (group0-chip0) value for the BARs Target* l_pTopLevel = nullptr; i_targetService.getTopLevelTarget(l_pTopLevel); ATTR_XSCOM_BASE_ADDRESS_type l_xscomBase = l_pTopLevel->getAttr(); ATTR_LPC_BUS_ADDR_type l_lpcBase = l_pTopLevel->getAttr(); // Loop through all the procs to recompute all the BARs // also find the victim to swap with Target* l_swapVictim = nullptr; std::map l_swapAttrs; TARGETING::TargetHandleList l_funcProcs; getAllChips(l_funcProcs, TYPE_PROC, false ); for( auto & l_procChip : l_funcProcs ) { TARG_INF( "Proc=%.8X", get_huid(l_procChip) ); // Set effective fabric ids back to default values ATTR_FABRIC_GROUP_ID_type l_groupId = l_procChip->getAttr(); l_procChip->setAttr(l_groupId); ATTR_FABRIC_CHIP_ID_type l_chipId = l_procChip->getAttr(); l_procChip->setAttr(l_chipId); // Compute default xscom BAR ATTR_XSCOM_BASE_ADDRESS_type l_xscomBAR = computeMemoryMapOffset( l_xscomBase, l_groupId, l_chipId ); TARG_INF( " XSCOM=%.16llX", l_xscomBAR ); l_procChip->setAttr(l_xscomBAR); // See if this chip's space now belongs to the master if( l_xscomBAR == l_curXscomBAR ) { l_swapVictim = l_procChip; TARG_INF( "Master Proc %.8X is using XSCOM BAR from %.8X, BAR=%.16llX", get_huid(l_pMasterProcChip), get_huid(l_swapVictim), l_curXscomBAR ); l_swapAttrs[ATTR_PROC_EFF_FABRIC_GROUP_ID] = l_groupId; l_swapAttrs[ATTR_PROC_EFF_FABRIC_CHIP_ID] = l_chipId; l_swapAttrs[ATTR_XSCOM_BASE_ADDRESS] = l_xscomBAR; } // Compute default LPC BAR ATTR_LPC_BUS_ADDR_type l_lpcBAR = computeMemoryMapOffset( l_lpcBase, l_groupId, l_chipId ); TARG_INF( " LPC=%.16llX", l_lpcBAR ); l_procChip->setAttr(l_lpcBAR); if( l_swapVictim == l_procChip ) { l_swapAttrs[ATTR_LPC_BUS_ADDR] = l_lpcBAR; } // Paranoid double-check that LPC matches XSCOM... if( ((l_lpcBAR == l_curLpcBAR) && (l_swapVictim != l_procChip)) || ((l_lpcBAR != l_curLpcBAR) && (l_swapVictim == l_procChip)) ) { TARG_ERR("BARs do not match : LPC=%.16llX, XSCOM=%.16llX", l_curLpcBAR, l_curXscomBAR ); TARG_ASSERT(false,"Mismatch between LPC and XSCOM BARs"); } //Setup Interrupt Related Bars ATTR_PSI_BRIDGE_BASE_ADDR_type l_psiBridgeBAR = computeMemoryMapOffset(MMIO_GROUP0_CHIP0_PSI_BRIDGE_BASE_ADDR, l_groupId, l_chipId); TARG_INF( " PSI_BRIDGE_BAR =%.16llX", l_psiBridgeBAR ); l_procChip->setAttr(l_psiBridgeBAR); if( l_swapVictim == l_procChip) { l_swapAttrs[ATTR_PSI_BRIDGE_BASE_ADDR] = l_psiBridgeBAR; } ATTR_XIVE_CONTROLLER_BAR_ADDR_type l_xiveCtrlBAR = computeMemoryMapOffset(MMIO_GROUP0_CHIP0_XIVE_CONTROLLER_BASE_ADDR, l_groupId, l_chipId); TARG_INF( " XIVE_CONTROLLER_BAR =%.16llX", l_xiveCtrlBAR ); l_procChip->setAttr(l_xiveCtrlBAR); if( l_swapVictim == l_procChip) { l_swapAttrs[ATTR_XIVE_CONTROLLER_BAR_ADDR] = l_xiveCtrlBAR; } ATTR_XIVE_THREAD_MGMT1_BAR_ADDR_type l_xiveThreadMgmtBAR = computeMemoryMapOffset(MMIO_GROUP0_CHIP0_XIVE_THREAD_MGMT1_BASE_ADDR, l_groupId, l_chipId); TARG_INF( " XIVE_THREAD_MGMT1_BAR =%.16llX", l_xiveThreadMgmtBAR ); l_procChip->setAttr(l_xiveThreadMgmtBAR); if( l_swapVictim == l_procChip) { l_swapAttrs[ATTR_XIVE_THREAD_MGMT1_BAR_ADDR] = l_xiveThreadMgmtBAR; } ATTR_PSI_HB_ESB_ADDR_type l_psiHbEsbBAR = computeMemoryMapOffset(MMIO_GROUP0_CHIP0_PSI_HB_ESB_BASE_ADDR, l_groupId, l_chipId); TARG_INF( " PSI_HB_ESB_BAR =%.16llX", l_psiHbEsbBAR ); l_procChip->setAttr(l_psiHbEsbBAR); if( l_swapVictim == l_procChip) { l_swapAttrs[ATTR_PSI_HB_ESB_ADDR] = l_psiHbEsbBAR; } ATTR_INTP_BASE_ADDR_type l_intpBAR = computeMemoryMapOffset(MMIO_GROUP0_CHIP0_INTP_BASE_ADDR, l_groupId, l_chipId); TARG_INF( " INTP_BAR =%.16llX", l_intpBAR ); l_procChip->setAttr(l_intpBAR); if( l_swapVictim == l_procChip) { l_swapAttrs[ATTR_INTP_BASE_ADDR] = l_intpBAR; } //finished setting up interrupt bars // Set the rest of the BARs... } // We must have found a match somewhere TARG_ASSERT( l_swapVictim != nullptr, "No swap match found" ); // Now swap the BARs between the master and the victim if needed if( l_swapVictim != l_pMasterProcChip ) { // Walk through all of the attributes we cached above SWAP_ATTRIBUTE( ATTR_PROC_EFF_FABRIC_GROUP_ID, l_pMasterProcChip, l_swapVictim, l_swapAttrs ); SWAP_ATTRIBUTE( ATTR_PROC_EFF_FABRIC_CHIP_ID, l_pMasterProcChip, l_swapVictim, l_swapAttrs ); SWAP_ATTRIBUTE( ATTR_XSCOM_BASE_ADDRESS, l_pMasterProcChip, l_swapVictim, l_swapAttrs ); SWAP_ATTRIBUTE( ATTR_LPC_BUS_ADDR, l_pMasterProcChip, l_swapVictim, l_swapAttrs ); SWAP_ATTRIBUTE( ATTR_PSI_BRIDGE_BASE_ADDR, l_pMasterProcChip, l_swapVictim, l_swapAttrs ); SWAP_ATTRIBUTE( ATTR_XIVE_CONTROLLER_BAR_ADDR, l_pMasterProcChip, l_swapVictim, l_swapAttrs ); SWAP_ATTRIBUTE( ATTR_XIVE_THREAD_MGMT1_BAR_ADDR, l_pMasterProcChip, l_swapVictim, l_swapAttrs ); SWAP_ATTRIBUTE( ATTR_PSI_HB_ESB_ADDR, l_pMasterProcChip, l_swapVictim, l_swapAttrs ); SWAP_ATTRIBUTE( ATTR_INTP_BASE_ADDR, l_pMasterProcChip, l_swapVictim, l_swapAttrs ); // Handle the rest of the BARs... } // Cross-check that what we ended up setting in the attributes // matches the non-TARGETING values that the XSCOM and LPC // drivers computed if( l_pMasterProcChip->getAttr() != LPC::get_lpc_bar() ) { TARG_ERR( "LPC attribute=%.16llX, live=%.16llX", l_pMasterProcChip->getAttr(), LPC::get_lpc_bar() ); TARG_ASSERT( false, "LPC BARs are inconsistent" ); } if( l_pMasterProcChip->getAttr() != XSCOM::get_master_bar() ) { TARG_ERR( "XSCOM attribute=%.16llX, live=%.16llX", l_pMasterProcChip->getAttr(), XSCOM::get_master_bar() ); TARG_ASSERT( false, "XSCOM BARs are inconsistent" ); } } #undef TARG_CLASS #undef TARG_NAMESPACE } // End namespace TARGETING